Binder parameter

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The Binder parameter^[1] in statistical physics is used to identify phase transition points in numerical simulations. It is defined as the kurtosis of the order parameter. For example in spin glasses one defines the Binder as

${B=\frac 1 2 \left( 3-\frac{\overline{\langle q^4\rangle}}{\overline{\langle q^2\rangle}^2} \right)}$

where $\langle\cdot\rangle$ stand for Boltzmann average, $\overline{\cdot}$ for average over the disorder and $q$ is the overlap between two identical replicas of the system. The phase transition point is usually identified comparing the behavior of $B$ as a function of the temperature for different values of the system size $L$ . The transition temperature is the unique point where the different curves cross. This is based on finite size scaling hypothesis, according to which, in the critical region $T\approx T_c$ the Binder behaves as $B (T, L) = b ((T - T c) L 1 / ν)$ .

[1]K. Binder, Z. Phys. B 43, 119 (1981)

[edit] References

^ K. Binder, Z. Phys. B 43, 119 (1981)

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This page was last modified 20:03, 26 January 2008 by Wikipedia user Betacommand. Based on work by Wikipedia user(s) Piopio1, SmackBot, Graeme Bartlett, Jeodesic and Regua and Anonymous user(s) of Wikipedia.
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